R2 C-terminal peptide inhibition of mammalian and ... - ACS Publications

Nov 1, 1993 - Alison Fisher, Fu De Yang, Harvey Rubin, Barry S. Cooperman ... LaMacchia , Elizabeth Helmbrecht , Barry S. Cooperman and Chris Dealwis...
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J. Med. Chem. 1993,36, 3859-3862

3869

R2 C-Terminal Peptide Inhibition of Mammalian and Yeast Ribonucleotide Reductase Alison Fisher: Fu-De Yang,+JHarvey Rubin,* and Barry S. Cooperman'J Departments of Chemistry and Medicine, University of Pennsylvania, Philadelphia, Pennsylvania 19104-6323 Received July 6, 1993.

Eucaryotic ribonucleotide reductases (RR) catalyze the reduction of ribonucleoside diphosphates to 2'-deoxyribonucleoside diphosphates. Each has an R12R22quaternary structure with each subunit playing a critical role in catalysis. Separation of the subunits results in loss of activity. Previous studies have demonstrated that peptides corresponding to the C-terminus of R2 disrupt subunit association by competion with R2 and have potential usefulness as therapeutics. Extensive structure-function studies have been carried out on peptide inhibition of herpes simplex RR in an effort to develop antiviral agents based on the observation that the herpes simplex R2 C-terminus, YAGAVVNDL, is quite different from the corresponding mammalian sequence. In this work we report a detailed structure-function analysis of peptide inhibition of mammalian and, to a more limited extent, Saccharomyces cereuisiae RRa. Our results for mammalian RR support the following conclusions with regard to the effect of substitution on inhibitory potency: (a) the N-acetylated R2 C-terminal heptapeptide N - A ~ P h e ~ T h r 3 ~ L e u ~ A s p ~ ~ A l a ~(N-AcF7TLDADF1) ~Asp~~Phe3~ is the minimal core peptide length required; deletion of the N-terminus or of middle positions (resulting in penta- and hexapeptides) results in large losses in inhibitory potency; (b) a free carboxylate is required on the C-terminal Phe; (c) Phe is strongly preferred to Leu in positions 1 and 7 and a bulky aliphatic group is preferred in position 5; (d) neither negative charge in positions 2 or 4 nor a polar side chain in position 6 are required for peptide binding, contrary to what evolutionary patterns in the R2 C-terminus of RR would suggest. S. cereuisiae RR displays a similar length dependence on the corresponding N-acetylated R2 C-terminal heptapeptide, N-AcFTFNEDF. This peptide has a 4-fold higher inhibitory potency toward S. cereuisiae RR than toward mammalian RR. Such selectivity raises the possibility that peptide analogs related to R2 C-termini can be developed as therapeutic agents even against organisms having R2 C-terminal sequences similar to that of mammalian RR.

Introduction Ribonucleotide reductase (RR) catalyzes reduction of an essential ribonucleotides to 2~-deoxyribonucleotides, step for de nouo synthesis of DNA. Eucaryotic RRs, which are the focus of this paper, in common with viral and E. Coli RRs, use nucleotide diphosphates as substrates and have an R12R22 quaternary structure. Enzyme activity is contingent upon association between the R1 and R2 dimers (K, 0.5-1 X lo7 M-')lt2 and is inhibited when the C-terminal peptide of R2 competes with intact R2 for association to Rl.1-7 Structure-function studies indicate that the inhibitory potency is critically dependent on the size (7-20 residues for RRs from different organisms) and sequence of the terminal ~eptide.~J'A considerable effort has been devoted to developing antiviral agents by exploiting peptide inhibition of herpes simplex RR,10J1 based on the observation that the herpes simplex R2 C-terminus,YAGAWNDL,differs substantially from the corresponding mammalian sequence. Eucaryotic R2s are highly homologous to one another up to seven residues from the C-terminus, at which point the homology is lost (Table I). We earlier demonstrated6 that the heptapeptide N-AcFTLDADF, corresponding to the C-terminus of mouse R2, would inhibit mammalian RR. Acetylation is necessary to neutralize the positive

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* Corresponding Author-Department of Chemistry, University of Pennsylvania,Philadelphia,PA 19104. Phone: 215-898-6330.FAX: 215898-2037,

Department of Chemistry.

* Department of Medicine. f

Abstract published in Aduance ACS Abstracts, October 15, 1993.

Table 1. Homologous R2 C-Terminal Sequences organism mouse clam human vaccinia

sequence

organism

sequence

FTLDADF Saccharomyces cerevisiae FTFNEDF FTLDADF Schizosaccharomyces pombe FTIDEDF FTLDADF Plasmodium falciparum FCLNTEF FSLDVDF R2 C-terminalsequencesextendfrom P h e to Phew, numbered according to the mouse sequence. Sequences may be found in the followingreferences: clam, mouse, vaccinia,and S.cereuisiae,ref 23; human, ref 24;S. pombe, ref 25; and P.falciparum, ref 15.

charge on the a-amino group, which otherwise interferes with binding. Here we extend this observation by determining how the inhibitory potencies of a series of mammalian R2 C-terminal peptide analogs depend on size and sequence and whether even the slight differences in the C-terminal sequences of Saccharomyces cereuisiae vs mammalian R2 can be exploited in developing peptides that show selectivity in the inhibition of the corresponding RR activities. Such selectivity could have important implications €orthe design of therapeutics targeted toward infectious organisms.

Results and Discussion The results of experiments measuring the relative inhibitory potencies (RIs) of mammalian R2 C-terminal peptide analogues are summarized in Table 11. RIs of the first seven peptides (1-7) confirm the importance of the C-terminal heptapeptide for binding to the R1 subunit. RIs of the N-acetyl octa- and nonapeptides are both 1(1, 21, showing a lack of effect on binding to R1 of increasing peptide length past the seventh position from the C-ter-

0022-2623/93/1836-3859$04.oo/o 0 1993 American Chemical Society

3860 Journal of Medicinal Chemistry, 1993, Vol. 36, No. 24

Table 11. Inhibitory Potency of Mammalian R2 C-Terminal Peptide Analogs toward Mammalian Ribonucleotide Reductase Activity peptide 1, Ac-NSFTLDADF 2,Ac-SFTLDADF 3,SFTLDADF 4,Ac-FTLDADF 5, FTLDADF 6,Ac-TLDADF 7,Ac-LDADF 8,Ac-LTLDADF 9,Ac-F(~'-NH~)TLDADF 10,Ac-F(4'-Ns)TLDADF 11, Ac-FSLDADF 12,AC-FALDADF 13,AC-FTVDADF 14,AC-FTFDADF

is,A~-FTKDADF

16, AC-FT€NADF 17,AC-FTLXADF

is,AC-FTLDGDF

19,AC-FTLDEDF 20,AC-FTLDAEF 21,AC-FTLDANF 22,AC-FTLDA~F 23,AC-FTLDAXF 24,A~-FTLDAISL 25,Ac-F-LDADF7deletion) 26,Ac-FTLD-DF (deletion) 27,Ac-FTL-DF (deletion) 28, Ac-FTLDADFM

ICso,' WM 9-15 8-20 80 8-20 >4w >400 >400 >400 100 100 40-42 35-40 30 48-58 207 25-29 286-336 110-230 28 450-620 32-38 29-30 34-35 >400 412 322 364-460 500

% RI 100 100 25 100